Automatic movable gate for dams



Maak 5, 1940. v. C. SMITH 2,192,510

AUTOMATIC MOVABLE GATE FOR DAMS do N Ln N m "n di? co o l@ nventor l` t -go' E o "om VCSMITH 00 L0 KO March 5, 1940. v. c. SMITH 2,192,510

AUTOMATIC MOVABLE GATE FOR DAMS Filed July 3, 1939 lO Sheets--Shee'll 2 v. c sMlTH AUTOMATIC MOVABLE GATE FOR yDAMS March 5, 1940.

1o sheets-sheet 5 Filed July 3, 1939 hwcntor V C. SM IT H AMM @i m March-"S, `1940.

X ne

v. c. sMlTH 2,192,510

AUTOMATIC MOVABLE GATE.FOR DAMS Filed July 5, 1939 1o sheets-sheet' 4 109 y IO7 nventor v. c. SMITH (Ittorneg k- WM?- March 5, 1940. v. c. s Mn'H AUTOMATIC MOVABLE GATE FOR DAMS Filed July 3, 1939 10 Sheets-Shet 5 VV (I) nventor v. c. SMITH Gttorneg March 5, 1940. v v c. SMITH Y2,192,510

AUTOMATIC MOVABLE GATE FOR DAMS Filed Jly s, 1959 1o sheets-sheet s Srwenfor V. C. SMITH March s, 1940. v. c. SMITH 2,192,510

AUTOMATIC MOVBLE GATE FOR DAMS Filed July 5, 1939 l0 Sheets-Sheet '7 UPSTREAM END OF DAM v `inventor V. C. SMITH' Lttorneg March 5, 1940.

V. C. SMITH AUTOMATIC MovABLE GATE Foa DAMS Filed .my s, 1939 10 Sheets-Sheet 8 |O5\ 9el G3 96 ,'00 9| l0 99 102 |02 79 9895 79" 959| A ez 97 j 98 9v gg |09 94 |03 IOL VL |o| 94 99 Y 92 99 92 l2 .y I n 05 |O5\p '2 v 53 96 es g |00 l 9( 102 95 |04 '94' 971 98 |09 103 94 lol 54 99 92 99 92 V. C. SMITH n March 5, 1940. I v. c. sMn'H r 2,192,510

, AUTOMATIC MOVABLE GATE FOR DAMS med July s, 193s 1o sheets-sheet 9 l l y C FL?. I3 '45 I4 F5514 65 |35 65 |35 '40 I ses H32 |42 |48 [33 i y |38 82 |31 *|43 4 e4 '35 -lsf |44 36 |34 |329 |37 `|29 A |34 |41 '39 'Fl' .I A 1+ 3 6 3 3| 33 FL? l 5 14s 52 S4 2| ||3Z59 l |37v |39 :so l y .I hf l l "f 1."

I Patented Mar. 5, 1940 UNITED- STATES PATENT 'GFFiICE l w l 2,192,510 j f AUTQMATIC MOVABLE GATE FOR DAMS Verl Chester Smith, York, Pa., assignor te S. Morgan Smith Company, York, Pa., a corporation oi Pennsylvania l i Y Application July 3, 1939,'.Serval No.282q695v v 15 Claims. Thisinvention `relates to dams and other hydraulic structures for damming water in streams,

and more particularly to movable structures or Vwater gates mounted on 'the crests of dams.

` An object oi the invention 'is to provide an improved movable' gatestructure adapted to be automatically operated so as to maintain a substantially uniform vpredetermined amount of head water at the upstream side of the dam. Another object ofthefinventionis to provide an improved operating mechanism for movable dam structures which is controlled by means actuated by variations in the level of the head water. u To the accomplishment of theioregoing and related ends, the invention, then, comprises the features hereinafter`-fullyI described, and particularly pointed out in the claims,` the following description and the annexed drawings setting `forth '20 in detail an illustrative embodiment of the nvention, this being indicative, however, of but one of the various ways in which the principle of the invention maybe employed.

In the accompanying drawings:

i5 Figure 1 is a vertical longitudinal section of the crest of a dam showing the movable gate and operating mechanism therefor of the present invention mounted thereon;

Fig. 2 is a vertical transverse section taken `i0 on the line 2--2 of Fig. 1;v

Fig. 3 is an enlarged elevation, partly in section, of the operating mechanism and control means therefor at one end of the dam;

. Fig. 4 is a diagrammatic View, partly in sec- 85 tion, of a portion of the controlmeans;

Fg. 5 is an elevation, partly in section, showing the relation of the control means to one of the operating cylinders;

Fig. 6 is a vertical ysection of a portion of the o dam structure showing .the well` for the float of the control means;

Fig. 7 is an elevation o f the means for supplying fluid under pressure to the operating mechanism, the dam structure being shown in vvertical section;

Fig. 8 is a plan or the structure shown in Fig.

7, the dam structure being shown in horizontal.

section;

being shown in neutral position;

Fig. 10 is a vertical section View of the control valve shown in Fig. 9, showing the" same in gate loweringposition;

Fig. 9 is a vertical longitudinal section of one f of the control valves shown in Fig. 3, the valve (Cl. (i1- 22) Fig. 11 is a view similar to Fig. 10 showing the valve in gate raising position; Fig. y12 is a vertical transverse section taken on the line I2-I2-of Fig. 9; v

Fig. 13 is averticallongitudinal section of the 5 other control Valve shown in Fig.l 3, the parts being shown in normal positionin'which` communication through the valve is maintained lto supply .theoperating cylinders with fluid under pressure; 10

Fig. 14 is a yvertical transversejsection taken on the line Ill-.I4 of Fig. 13; Fig. 15 is a view similar to Fig. 13 showing the valve in the position in which luid'is exhausted from the' operating cylinders of the apparatus; l5 Fig. 16 is a vertical transverse section of one Cof the gate bearings'taken on'theline IIi-IS of of the dam which extends across the stream may be of any height with respecty to the bed of 'the' stream and has a sill I2 formed'in its upper portion or crest (see Figs. 1 and 2). f

At each end of the crest of the dam there are il()r y upstanding end walls, one of which is indicated at I3 and the other being designated I4.

' When the width ofthe lstreaml is considerable and more than one gate is'required for daniming up the water, the intermediate end walls may be 35 f in the form of piers.

`A tunnel I5 is formed longitudinally. in the damin proximity to the sill I2. Thepier 'or end wall I3 has a vertical chamber Iformed therein vand the pier or end wall I dhas a vertical chamber I1 formed therein. The vtunnel and said chambersvprovide means in the dam structurefor accommodating operating andcont'rol `mechanism of the` apparatus.

The end walls I3 and I4, respectively, have openings I9 and 20 formed therein for the ends 2| and 22, respectively, of a rotatable member or gate 23, which is radapted to maintain the head water at a predetermined level.

The gate 23 comprises a'cylindric'al body por- 55 tion Zfand an arcuate shield 25 which .extends outwardly from the cylinder 24 and is heldrigid` therewith by means of a plurality of plates 26.

Theplates 26 are disposed transversely with r e spectjto the longitudinal axis of the gate. An

angle iron 27 may also be provided along the outer edge of the shield 25. Preferably the gate is constructed of sheet metal, such as plate steel. The cylinder 2li should be of suflicient diameter and strength to render the same proof against distortion. The gate structure provides a flap gate in which the flap is rigidly connected to the cylinder 2t. l

Water gates of the type herein shown and described may be constructed of any length, and in some instances the gates have a length of one hundred feet and more. When the gates are constructed of such length it is necessary to construct the parts thereo;F in short sections which can be easily assembled, and to join `the several sections together in the fieldv to form a unitary structure.

In the present instance the gate 23 is shown as being composed of three sections 2id, 29 and 36. The plates 25 are so disposed that at the adjoining ends rol? the sections the plates abut, as shown in Fig. l, and these abutting plates are adapted to be secured face torace together by bolts, rivets or the like fastening elements.

The ends 2i and 22 of the gate are carried by suitable bearings 3l, one of whichv is shown in detail in Fig. 16.

Each bearing 3i is anchored to the dam structure H and has a bushing 32 which engages a sleeve 33 mounted on each a shim Sii being interposed between the sleeve and the cylinder so as to permit alinement of the cylinder in the bearings when the device is being assembled.

Between the main bearings 3l, the gate is supported on a plurality of bearings 35 (see Figs. 1 and 2), which are mounted on the sill i2. bearings 35 are semi-circular in form, being open at the top and permit free turning movements of the gate structure.

Mounted in the top of the dam structure H and coextensive therewith between the end walls or piers i3 and l, is an I-bearn 35 having upper and lower horizontal anges 3'! and 38, respectively, which anges extend downstream with respect to the crest of the dam and overlie the Asill l2.

rIhe upper flange 3l' of the I-beam 35 supports a horizontally disposed plate 39 which extends downstream from the crest ofthe dam structure H to a'point adjacent to the junction of the shield 25 with the cylinder 24 when the gate 23 is in raised position, as shown in Fig. 2.

The plate 39 overlies a flexible sealing strip lll] carried by the lower flange 3S of the I-beam 36 and serves as means for protecting said sealing strip from debris floating down the stream.

The sealingstrip ill is coextensive with the cylinder 24 and makes a rubbing contact with said cylinder at all times and irrespective of the position of the gate shield 25 so as to `prevent leakage of water beneath the bottom portion of i the gate.

The walls of the piers i3 and lil are formed with armature plates lil against which bear sealing means t2 carried by end shields at each end of the gate Z3, as shown in Fig. 1-

The extremity of the cylinder 211 which is disposed in the chamber it carries a crank l5 and the extremity of said cylinder which is disposed in the chamber il carries a crank it (see Figs. l and 2).

Mounted in the pier I3 and disposed above the chamber i6, is a cylinder All, in which is mounted a piston d8 having a rod i9 which is connected end of the cylinder,l

TheI

, of the cylinders t7 and 5l, respectively, and are retained in such position by `iiuid under pressure supplied to the chambers 55 and 55 beneath said pistons, respectively, in the manner to be hereinafter more fully described.

Fluid under pressure from a fluid pressure tank 5l (see Figs. '7 and 8) is delivered through a pipe line SZ, control valvei', pipeline 64, and control valve to a pipeline 55 which extends down into the tunnel. l5 (see Figs.' 1, 3 and 5). The end of the pipe 65 in the tunnel is connected by a T connection 52 totwo pipes 68 and 59. The pipe 633 leads tothe chamber 55 of the power cylinder-til, and thepipe Si? is connected to the chamber 5t of the Apower cylinder 5I. This arrangement oi the parts is such that both chambers 55 and '5.5 are supplied with fluid under subtrol valve 65 by a pipe 85, T connection 8l, and' pipe 22. l

The T connection 'lll is connected to a sump tank 83 by a pipe 84 (see Figs. 3, 7 and 8).

Fluid under'pressure is adapted to be transferred from the sump tank 33 to the ltank 6I by CII an electric motor driven pump 85, as shown in Figs. 7 and 8. In the present instance oil is used as the fluid, and the pump 85 is adapted to be automatically controlled in well known manner so as to maintain the pressure of the oil in the tank 6l of a predetermined amount at all times. T

As shown in Figs. 9, 10, l1 and l2, the control valve 53 comprises a casing formed witha cylindrical bore 9| in which is mounted a plunger 92 formed with spaced heads 93 and 94.

Chamber 9'! of the control valve 63 is connected to the fluid pressure pipe 62, by a port 98.

The chambers S6 and 99 of the control valve B3 are connected to the pipe 19, by ports Elli) and IDI, respectively, and a passage |02.

The chamber 0 3 of the control valve 63 is connected to the pipe 64, by a port 04, and the chamber is blank.

'As shown in Figs. 9 and 12, when the plunger 92 is in neutral position, such as the position in which the gate 23 is held raised, as shown in Figs. 1 and 2, fluid under pressure delivered` to the cylinders 5 and 55 vthrough pipes, E8 and 69 (Fig. l) is bottled up, since the port HM is lapped by plunger head 54,*thereby cutting oi communication from the control valve 63 to pipe 64. l

At the same time, iluid under .pressure from the tank 5| which is delivered to the control valve water in the pool on ations in water level E plunger and of the link |01 with the lever |08 is adjacent to the pivot as indicated at ||3. The pivotal connection of the link |01 with the lever |06 is indicated at |I4. The arm is rigidly fixed to the piston rod 49 and extends laterally therefrom so that when the piston rod moves downwardly and upwardly the arm I0 will be carried therewith and through the connection of the arm ||0 with link |09 the levers |06 and |08 will be operated, the lever |08 moving about the xed pivot and the lever |06 moving about movable pivots, as will be hereinafter more fully described.

The end of the floatinglever |06 opposite -to the end having the pivot ||4, is pivotally connected, as at I5, to the lower end of a link I6.

The upper end of the link ||6 is pivotally connected, as at ||1 to a lever H9.

The lever H8, adjacent to the pivot ||1 is pivotally connected, as at I |9, to a support |20.

, lThe lever ||8 extends beyond the pivot ||9 and carries a weight |2|.

The end of the lever ||8 opposite to the end having the weight |2| is pivotally connected, as at |22, to the rod |23 of a float |24 (seev Figs. 3, 4 and 6).

The oating lever |06 and its operating means constitutes compensating mechanism to prevent over traveling of the gate 23, as will be hereinafter more fully described.

The end wall or pier |3 is formed with a vertically disposed well |25 disposed (see Figs. 6 and 8) The well |25 extends from the upper portion of the end wall or pier |3 downwardly to a point where the float |24 can be located in water from the pool on the upstream side of the dam and `in order that water from such pool can be supplied to thewell, the bottom portion of said wellis connected to the pool by means of a pipe |26 (see Figs. 6 and 8).

' The construction of the oat |24, the well |25 and the pipe |26 is such that the iioat is supported by the water in the well at a predetermined height and the level of the water in the well is maintained at the same level as the level of the the upstream side of the dam, so that when the level of water in the pool changes, a corresponding change will be effected inthe level of the water in the well, such fluctugate mechanism by actuating 63 in the manner to be hereoperation of the the control valve inafter described.

As'shown in Figs. 13, 14 and l5, the control valve 65 comprises a casing formed with a cylindrical bore |31, in which is mounted a plunger |32 formed with spaced heads. |33 and |34.

The upward movement of the plunger |32 in the bore |3| is limited by a collar |35 carried by said adapted to contact the upper end of the bore |3|, as shown in Figs. 13 and 14.

The plunger |32 is urged upwardly by an expansible coil spring |30 encircling the stem of said plunger and bearing at one end against the underside of the head |34 and at the other end against the bottom of the bore |3|.

' The chamber |36 of the control valve 65 is connected to the pipe 64 by a port |31.

,The chambers |38 and |39 of the control valve in which the loat |24 is being effective in initiatingl |4I, respectively, and passage |42.

The chamber'l43 isconnected to the pipe 66, by aport |44, `and theV chamber |29 is blank, as shown in'Figrll.

As shown in Figs. 1 3 and 14, when the plunger |32 is invnormal or raised position, the chambers |36 and |43 are connected so that communication'is ,maintained through the control valve 65 between pipes 64'and 66.

65l are connected to the pipe 82, by ports |40 and At the same time chambers |38 and |39 are c connected-to the sump tank 83, through passage |42, and pipes182, l16 and 04 (see Figs. lfand. 13). The plunger |32 has a stem |45 (Figs. 3 and y18) which is connected to the stem |46 of a piston |41 disposed ina bore |48 of an unloader valve device |49.

In addition to the bore |48, the unloader valve |49 is also formed'with bores |50, |5| and |52 -(see Figs. 17 and19).y

The bore constitutes a chamber which is connected to the T connection 8| heretofore referred to by a pipe-|53 (see Fig. 3).

The bore |52 constitutes a chamber which is connected to the pressure line. pipe 62 by a pipe |54 and a T connection |55.

Mounted in the bore |50 is a plunger 56 formed 'with spacedheads |51, |58 and |59 which iit fairly snugly v'within said bore.

Below the head |59, the plunger |56 is formed with a reduced'downwardlyextending portion |60 which is mounted in abore l6|.

The bore |61 extends downwardly to the bottom of the unloader valvecasing where it is connected to' one end of a'pipe |62. The other end of the pipe |62 is connected to the pipe 66, as indicated at. |63 (Fig. 3), so that fluid under pressure in the pipe.' 66 is conducted to the bore |61` and acts on the bottomof the portion |60 of the plunger |56.

Slidably mounted in a bore |66 of a tubular supporting member |61 mounted on top of the casing .of the unloader valve device |49, is a ro'd the other side of the pisber |16 by a passage |11, and the chamber |52 is also connected to a chamber |18, by a passage |19.

Since the chamber |5| is connected to the sump tank 03 through the pipe |53, said chamber functions as means for draining surplus operating iiuid from the unloader valve device |49. Accordingly,

the chamber |5| is connected to several portions ofthe bore |50 by passages |00,r |8| and |82.

Beneath the head |59 of the plunger |56 and at the junction of the lowerportion of the bore |50 with the bore |6| there is a shoulder |83 against which the plunger |56 rests under normal operating conditionsv of the apparatus. When the plunger |56 is in such position (see Fig. 17) fluid under pressure delivered to the unloader vvalve |49 through pipe |62 and flowing past the portion of the plunger, the uid will be delivered to the chamber |5| through.

passage |82. From the chamber the uid returned to neutral position, the iiuld under will be returned to the sump tank. pressure in piston chambers 55 and 56 will act Fluid under pressure delivered to the cham- 0n the pstOIlS 48 and 52, respectively, s0 that the ber |52 by the pipe |54 will be bottled up in gate 23 is held. in a lower position than the chamber |52 since the plunger heads |58 and position shown in Fig. 2, which position of the l |59 cut on chamber |16 and passage |11, and gate permits sufficient water to iiow over the dam the passage |19 is lapped by the plunger head to reduce the level ofthe head water. |59. When the level of the head water has thus been As shown in Figs. 4 and 6, the desired level of decreased to a point corresponding substantially head water to be maintained at the upstream to the point indicated at HW (1), Fig. 4, the 1l side of the dam is indicated at HW (I) and downward movement of the float effects down- HW (2). When the level of the water is at ward movement ofthe plunger 92 of the control HW (l) the water will be approximately at the valve 63 so that the chamber |03 is connected to top of the gate 23 (see Fig. 2). 'I'he point HW the chamber 91, as shown in Fig. l1. (2) indicates a point above the top of the gate In this position of the control valve 63 fluid un- 1c -23 at which the maximum desired amount 0f der pressure from the pressure tank 6| is supplied water will iiow over the gate. In Fig. 4 the to the cylinders 55 and 56, in the manner previfloat |265 and the leverage mechanism connected ously described, and the pistons 48 and 52 will be thereto are shown in the position in which it is raised, thereby raising the gate 23 to the position assumed that the level of the head water is bewhereby the head water will be at the desired tween the points indicated at HW (l) and HW level. (2). Should the level of the head water be below In actual practice it has been found that the the point indicated atHW (l), thermechanism level of the head water will vary between the point will not function, since it is desired to retain indicated at HW (l) and HW (2),Fig. 4, without the gate 23 in upright Vposition so that water effecting operation of the control valve 63 in the 25 owing down stream will be dammed up. manner heretofore described. In other words, When the level of the head water increases slight variations in the level of the head water above the point indicated at HW (2), the float will not be eiective to cause operation of the |24 will rise in the float well |25 an amOunt control mechanism. This is advantageous, since f suflicient to effect operation of the Control meChitis only desired to lower or raise the gate 23 when 30 anism 0f the apparatus and the level' ||8 Will appreciable variations occur in the level of the be swung upwardly about its fixed pivot I9. head water, Accordingly, the leverage mecha- This upward movement of the lever 8 results niszn which is connected to the stem |65 of the in the link |6 being pulled upwardly and C011- plunger 92 is adapted to be moved by the iioat sequently the oating lever |06 will be moved through a range or distance substantially the 35 position shown in Fig. 9 to the position shown scyibedabout the pivot I M. distance shown in Fig. 4 between HW (l) and When the oatlng lever |06 1s mOved upwardly HW (2) before the control valve plunger 92 is about the pVOt H4, the plunger 92 0f the C011- moved an amount suiiicient to eiiect operation of trol valve 63 is pulled upwardly from the neutral the apparatus in the in Fig. 10. During the normal operation of the apparatus When 'the plunger 92 S thus actuated the iiuid under pressure supplied to the piston champlungel head 94 is mOVed upwardly thereby esbers 55 and 56 is also supplied to the bottom portablishing communication between chambers 99 tion 50 of the plunger g55 cf the unloader Valve and |03 of the control valve 63. device M9, through pipe |62 (see Figs. 3 and 17). 45

The DSOII Chambers and 110W be HOM/ever, Since the W |03 and 99, port |0|, passage |02, and pipes 19, Operating fluid j '14, la and 3,4 (see Flgs- 1., 3, 7 and" 0) that the fluid supplied through pipe |62 to the Fluid unoer pressure 1n the chambers 5 5 and bottom of the plunger overcomes the downward 56 which acts against the underside of the pistons pressure of the Weights 48 and 52 110W llOWs t0 the Sump tank and the Under normal conditions the pressure of the gate 23 commences to swing downwardly and fluid n the Cylinders 55 'and 53 rearwardly towards the dotted line position indithe underside of the pistons 43 and 52, respec cated in Fig. 2, due t0 the plessure 0f the Water tively, is sufficient to retain the gate 23 raised.

aetug against the upstream Side 0f the gate- When the pressure against the upstream face When the gate 23 thus moves downwardly the of the gate 23 becomes excessive, due to heavy pistons dit and 52 will move downwardly in the formations of cylinders 4l and 5|, respeetlvelv- Y and other foreign matter in the pool, and other This downward movement 0f the plStOnS 48 causes, this increase in pressure will be transand 52 results in the level |93 being moled dOWnmitted through the cranks i5 and 16 to the pistons wardly about its XeCl plVCt thereby Causing 610 and 52, respectively, so that the pressure of the @ad of the floating lever |06 having the pvot the huid in the chambers 55 and 56 is increased.v 65 llt to be moved dOWHWaldly, Sad level' |05 This increase in iiuid pressure is effective to raise swinging abeut the fulelum pfevl'ded by the plVOt the plunger |56 of the unl'oader valve device |49. H5. In this Way the COIItTGl Valve plunger 92 is The upward'movement of the plunger |56 moves returned to the position in which comrn1.1nication the head 553 upwardly an amount suicjenf, to

)between chambers 99 and |63 is cutoi, and over Cmmgt passage 'l with passage |13, thereby 70 f control val traveling 0f the gate is preventedpermiting iiuid under pressure which is supplied The-fluid under pressure Supplied t0 the Chamto the chamber |52 by pipe |54, to flow into chamber 9i' by pipe 62 wi'il be bottled up in said chamber 1|. y ber during the above described operation of the The increase in pressure of iiuid in chamber ve 63, and when the plunger 92 is thus acting against the top ofthe piston |41, causes 75 ncreases an amount suiicient so acting against ice, accumulation of logs, debris,

A with are adapted to function only communication through the control valve 65 from pipe B4 to pipe 66 is cut off and pipe E6 is connected to the sump tank 83, through port |44, chambers |43 and |3il, port |40, passage-|42, and pipes 82, 16 and 34 (see Figs. l and 3).

The cylinders 55 and 56 are now connected to the sump tank 83, through the control valve 35,-

and the apparatus operates in the manner heretofore described to lower the gate 23.

When the plunger |56 .of the uploader valve |49 has been moved upwardly inthe manner heretofore described the plunger head`y|59 will uncover passage |19 so thatfluid under pressure is admitted to the chamberv |13 onthe underside of the plunger head |59. In this way the plunger |56 is maintained in raised position. y

The gate 23 will. in this way. be lowered completely and rest on the sill of the dam When it is desired to restore the operating mechanism to an active condition so that the gate 23 can be raised, valve |85 (Fig. 3) is operated to cut oli communication through the pipe |54 so as to relieve the pressure of the fluid' acting against the plunger |56. When the valve `H is closed. fluid will drain through passage |82 into chamber l5! and from thence the iluid will flow back to the sump tank 83.

Upon the reduction of fluid pressure acting on the plunger |55 the weights |59 will move the plunger |55 downwardly to the position shown in Fig. 15. In this way the iluid underpressure in chamber |1| acting on the ton of the piston M1 is reduced. since chamber |1| lis also connected to the drain chamber |5l. through passage |13.

chamber l|12 and passage 13|. The spring |33,

acting against the plunger |32 then returns the control valve B5 to the normal position shown in Fig. 13.

Since the iioat |26 will be down below the position shown in 4. the plunger i12-'of the control valve 33 will also be in the position in which uid under pressure from pipe 62 is supplied through chambers 91 and |03 to the pipe M. from which pipe the fluid under pressure is delivered to the piston chambers 55 and 5E sothat the pistons Mi. and 52 are moved upwardly. thereby returning the gate to the raisedror upright position shown in Figs. 1 and 2.

Since the control valve 35. themunloader valve M9. and the parts operatively associated thereunder extraordinar;T pressure conditions. as has'been heretofore described. when installations of the` apparatus are ma de where such extraordinary pressure conditions may not exist. these elements may be dispensed with. In such case the pipes 64 and 55 may be connected as shown bv the pipe indicated by dotted lines 81 in Fig.4 3.

The control valve 53 will function in the manner heretofore described to control communication of the iiuid pressure lines to the power cylinders 11 and 5| so that the gate 23 will be lowered when the head water level exceeds a predetermined amount. f

Having thus described my invention, what I claim is: l

l. In a dam. the combination of a rotatablir mounted gate for maintaining the head water at a predetermined level, a crank arm extending laterally from each end of the gate, a power pis'- ton in a cylinder at each end of the gate, means connecting each piston with each cranky arm, respectively, a source of supply of Vfluid under pres-f sure, a pipe line connecting both power cylinders, a valve for controlling the fluid under pressure from said source to said pipe line and adapted to maintain fluid bottled up in the pipe line when the gate is in normal position, a float operated by the head water, a floating lever operatively connected to said valve, means operatively connecting said float with said floating lever, 'and means connecting said floating lever with said means connecting a piston with a crank arm;

2. In a dam, the combination of a. rotatably mounted gate for' maintaining the head Water at a predetermined level, a crank arm extending laterally from each end of the gate, a power pistonin a cylinder at eachend of the. gate, means connecting cach piston with each crank arm. a source of supply of fluid under pres-A sure, a pipeline connecting both power cylinders, a valve for controlling the fluid under pressure from said source of supply to said pipe line and y adapted to maintain fluid bottled up in the pipe.

line when the gate is in normal position, and means operated by variations in the head water level for' controlling the operation of said valve.

3. In a darn, the combination'of a vrotatably mounted gate for maintaining the headwater at'A a predetermined level, a crank arm extending laterally from each end `of the gate, a power cylinder at each end of the gateoperatively connected to each crank arm, a source of supply of,

fluid under pressure, a pipe line extending across the darn and connecting both power cylinders, means for controlling the. fluid under pressure' from said source of supply to said pipe line, a iioat operated by the head water, means operatively connecting said float with said fluid pres',-

sure controlling means, and means connecting ga.

said iiuid pressure controlling means with'the means connecting a power cylinder with a crank arm.

4. In a dam, the combinationl of a rotatably mounted gate for maintaining the head water at' a predetermined level, fluid pressure operated means adapted to maintain saidy gate in normal position, aiioat operated by the head water, ay

valve controlling the fluid pressure of said fluid pressure operated means, a floating lever operatively connected to said valve, means operatively connecting said float with said floating lever, and

means connecting said iiuid pressure operated means with said floating lever.

5. In a dam, a gate rotatably mounted on saidl dam and having a shield adapted to project up.- wardly above the top of the dam, a crank arm extending laterally from each end of the gate, a power cylinder at each end oi the gate operatively connected to each crank arm to raise and lower the shield, a source of supply of fluid under pressure, a pipe line extending across the dam and beneath the gate and connecting both power` cylinders, and means for controlling the fluid under pressure from said source of supply to said pipe line.

6. In a dam, the combination oi a rotatably mounted gate for maintaining the head water at a predetermined level, uid pressure operated means adapted to maintain said gate in `normal position, and means operable by an increase of head water level above a. predetermined height to relieve fluid pressure acting on said uid pressure operated means to thereby permit the gate to move to a lower discharge position.

l'1, In a dam, a gate rotatably mounted on said dam and having a shield adapted to project up- Wardly to provide a head Water pool of a desired level, a source of supply of iluid under pressure, fluid pressure operated means operatively connected to said gate and adapted to maintain said gate in its normal position, a valve controlling communication from said source of supply of iluid and said iluid pressure operated means, and means operated by an increase of head Water for actuating said valve so as to relieve the lluid pressure acting on the gate operating means to thereby permit said gate to move to a discharge position.

8. In a dam, a gate urged to a discharge position by gravity, fluid pressure operated means operatively connected to said gate and adapted to maintain said gate in its normal position, and

a valve operated by an abnormal increase of head Water pressure to relieve the fluid pressure acting on said means to thereby permit the gate to move to a discharge position.

9. In a dam, a gate comprising a cylindrical portion rotatably mounted on said dam and a shield rigidly connected to the cylindrical portion and adapted to project upwardly above the top of the dam, an I-beam carried by said dam and parallel relationship with said gate, a

disposed in juxtaposed parallel relationship with said gate, and a flexible member secured to said I-beam and coextensive with said gate and having a rubbing contact with said cylinder forsealing the joint between the vdam and said gate.

` l0. In a dam, a gate, means for rotatably supporting said gate on said dam, an I-beam carried by said dam and disposed in juxtaposed exible member secured to said I-beam and coextensive With said gate for sealing the joint-between the dam and the gate, and means also carried by said I-beam and overlying said flexible member to protect the ilexible member from debris and other foreign matter.

1l. In a dam, the combination of a rotatably mounted gate for maintaining the head Water at a predetermined level, fluid pressure operated means to maintain said gate in its normal position, a source of supply of fluid under pressure, a valve for controlling the iluid under pressure from said source to said fluid pressure operated means and adapted to maintain uid bottled up in the iluid pressure operated means While the gate is in its normal position, means operated by an increase of head Water to operate said valve to relieve the uid pressure acting on said lluid pressure operated means to thereby permit the gate to move to a discharge` position, a second control Valve for controlling the fluid under pressure from said source to said uid pressure operated means and adapted to normally maintain communication from thensource of supply to said luid pressure operated means, and means operated by an abnormal increase of head water pressure to actuate said second control valve to relieve the iluid pressure acting on said iluid pressure operated means to thereby permit the gate toy move to a discharge position independent of operation ofthe ilrst control valve.

12. A movable dam element comprising a cylinder, a plurality of bearings mounted in spaced relation onthe crest of the dam for rotatably supporting said cylinder, and a continuous shield fastened to vsaid cylinder and extending laterally therefrom, the intermediate bearings being open at thel top to permit free movement of the shield from its uppermost to its lowermost posi- 'tion on the dani when the cylinder is rotated.

13. In a Water gate forv streams and the like, the combination with a flap gate opening in the direction of Water iloW and arranged to be opened when the height of the head Water exceeds a predetermined amount, fluid pressure operated means to maintain said gate in its normal position, a control valve for controlling fluid under pressure supplied to said means, a iloat operable by variations in head Water level for actuating said control valve, and compensating mechanism operated by said fluid pressure operated means to prevent the gate from over traveling. y

ll. In a Water gate for streams and the like,

vthe combination with a flap gate opening in the direction of Water means to maintain tion, a control valve for controlling fluid under pressure suppliedV to said means, means operable when the height of the head Water exceeds a predetermined amount for actuating said control valve, a second control valve for controlling fluid under pressure supplied to said gate operating means, and means operable by an abnormal increase of head water pressure for actuating said second control valve independently of the rst control valve to thereby permit the gate to move to a discharge position.

15. In a Water gate for streams and they like, the combination with gate opening in the direction of Water lloW, means for maintaining said gate in its normal position, means operable by an increase in head Water level for lowering the gate, and means operable independently of said head Water level operated means and actuated by excessive head Water pressure for lowering said gate.

ilovv, fluid pressure operated VERL CHESTER SMITH.

said gate in its normal posif 

